Multi-cell masks and methods and apparatus for using such masks to form three-dimensional structures
Multilayer structures are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. Selectivity of deposition is obtained via a multi-cell controllable mask. Alternatively, net selective deposition is obtained via a blanket deposition and a selective removal of material via a multi-cell mask. Individual cells of the mask may contain electrodes comprising depositable material or electrodes capable of receiving etched material from a substrate. Alternatively, individual cells may include passages that allow or inhibit ion flow between a substrate and an external electrode and that include electrodes or other control elements that can be used to selectively allow or inhibit ion flow and thus inhibit significant deposition or etching. Single cell masks having a cell size that is smaller or equal to the desired deposition resolution may also be used to form structures.
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This application claims benefit to U.S. Provisional Patent application No. 60/429,483, filed Nov. 26, 2002 and to U.S. Patent Application No. 60/415,371, filed Oct. 1, 2002, both of which are incorporated herein by reference as if set forth in full.
FIELD OF THE INVENTIONThe present invention relates generally to the field of three-dimensional structure fabrication. In some embodiments, meso-scale or microscale structures are formed via electrochemical operations (e.g. Electrochemical Fabrication or EFAB™ processes, such as electrochemical deposition operations and/or etching operations). In some embodiments the structures are formed via deposition of a single layer of material while in other embodiments the structures are formed via a layer-by-layer build up of deposited materials. In particular, selective patterning of effective deposition regions occurs via one or more masks having independently controllable regions.
BACKGROUNDA technique for forming three-dimensional structures (e.g. parts, components, devices, and the like) from a plurality of adhered layers was invented by Adam L. Cohen and is known as Electrochemical Fabrication. It is being commercially pursued by Microfabrica Inc. (formerly MEMGen® Corporation) of Burbank, Calif. under the name EFAB™. This technique was described in U.S. Pat. No. 6,027,630, issued on Feb. 22, 2000. This electrochemical deposition technique allows the selective deposition of a material using a unique masking technique that involves the use of a mask that includes patterned conformable material on a support structure that is independent of the substrate onto which plating will occur. When desiring to perform an electrodeposition using the mask, the conformable portion of the mask is brought into contact with a substrate while in the presence of a plating solution such that the contact of the conformable portion of the mask to the substrate inhibits deposition at selected locations. For convenience, these masks might be generically called conformable contact masks; the masking technique may be generically called a conformable contact mask plating process. More specifically, in the terminology of Microfabrica Inc. (formerly MEMGen® Corporation) of Burbank, Calif. such masks have come to be known as INSTANT MASKS™ and the process known as INSTANT MASKING™ or INSTANT MASK™ plating. Selective depositions using conformable contact mask plating may be used to form single layers of material or may be used to form multi-layer structures. The teachings of the '630 patent are hereby incorporated herein by reference as if set forth in full herein. Since the filing of the patent application that led to the above noted patent, various papers about conformable contact mask plating (i.e. INSTANT MASKING) and electrochemical fabrication have been published:
- (1) A. Cohen, G. Zhang, F. Tseng, F. Mansfeld, U. Frodis and P. Will, “EFAB: Batch production of functional, fully-dense metal parts with micro-scale features”, Proc. 9th Solid Freeform Fabrication, The University of Texas at Austin, p 161, August 1998.
- (2) A. Cohen, G. Zhang, F. Tseng, F. Mansfeld, U. Frodis and P. Will, “EFAB: Rapid, Low-Cost Desktop Micromachining of High Aspect Ratio True 3-D MEMS”, Proc. 12th IEEE Micro Electro Mechanical Systems Workshop, IEEE, p 244, January 1999.
- (3) A. Cohen, “3-D Micromachining by Electrochemical Fabrication”, Micromachine Devices, March 1999.
- (4) G. Zhang, A. Cohen, U. Frodis, F. Tseng, F. Mansfeld, and P. Will, “EFAB: Rapid Desktop Manufacturing of True 3-D Microstructures”, Proc. 2nd International Conference on Integrated MicroNanotechnology for Space Applications, The Aerospace Co., April 1999.
- (5) F. Tseng, U. Frodis, G. Zhang, A. Cohen, F. Mansfeld, and P. Will, “EFAB: High Aspect Ratio, Arbitrary 3-D Metal Microstructures using a Low-Cost Automated Batch Process”, 3rd International Workshop on High Aspect Ratio MicroStructure Technology (HARMST'99), June 1999.
- (6) A. Cohen, U. Frodis, F. Tseng, G. Zhang, F. Mansfeld, and P. Will, “EFAB: Low-Cost, Automated Electrochemical Batch Fabrication of Arbitrary 3-D Microstructures”, Micromachining and Microfabrication Process Technology, SPIE 1999 Symposium on Micromachining and Microfabrication, September 1999.
- (7) F. Tseng, G. Zhang, U. Frodis, A. Cohen, F. Mansfeld, and P. Will, “EFAB: High Aspect Ratio, Arbitrary 3-D Metal Microstructures using a Low-Cost Automated Batch Process”, MEMS Symposium, ASME 1999 International Mechanical Engineering Congress and Exposition, November, 1999.
- (8) A. Cohen, “Electrochemical Fabrication (EFAB™)”, Chapter 19 of The MEMS Handbook, edited by Mohamed Gad-El-Hak, CRC Press, 2002.
- (9) Microfabrication—Rapid Prototyping's Killer Application”, pages 1–5 of the Rapid Prototyping Report, CAD/CAM Publishing, Inc., June 1999.
The disclosures of these nine publications are hereby incorporated herein by reference as if set forth in full herein.
The electrochemical deposition process may be carried out in a number of different ways as set forth in the above patent and publications. In one form, this process involves the execution of three separate operations during the formation of each layer of the structure that is to be formed:
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- 1. Selectively depositing at least one material by electrodeposition upon one or more desired regions of a substrate.
- 2. Then, blanket depositing at least one additional material by electrodeposition so that the additional deposit covers both the regions that were previously selectively deposited onto, and the regions of the substrate that did not receive any previously applied selective depositions.
- 3. Finally, planarizing the materials deposited during the first and second operations to produce a smoothed surface of a first layer of desired thickness having at least one region containing the at least one material and at least one region containing at least the one additional material.
After formation of the first layer, one or more additional layers may be formed adjacent to the immediately preceding layer and adhered to the smoothed surface of that preceding layer. These additional layers are formed by repeating the first through third operations one or more times wherein the formation of each subsequent layer treats the previously formed layers and the initial substrate as a new and thickening substrate.
Once the formation of all layers has been completed, at least a portion of at least one of the materials deposited is generally removed by an etching process to expose or release the three-dimensional structure that was intended to be formed.
The preferred method of performing the selective electrodeposition involved in the first operation is by conformable contact mask plating. In this type of plating, one or more conformable contact (CC) masks are first formed. The CC masks include a support structure onto which a patterned conformable dielectric material is adhered or formed. The conformable material for each mask is shaped in accordance with a particular cross-section of material to be plated. At least one CC mask is needed for each unique cross-sectional pattern that is to be plated.
The support for a CC mask is typically a plate-like structure formed of a metal that is to be selectively electroplated and from which material to be plated will be dissolved. In this typical approach, the support will act as an anode in an electroplating process. In an alternative approach, the support may instead be a porous or otherwise perforated material through which deposition material will pass during an electroplating operation on its way from a distal anode to a deposition surface. In either approach, it is possible for CC masks to share a common support, i.e. the patterns of conformable dielectric material for plating multiple layers of material may be located in different areas of a single support structure. When a single support structure contains multiple plating patterns, the entire structure is referred to as the CC mask while the individual plating masks may be referred to as “submasks”. In the present application such a distinction will be made only when relevant to a specific point being made.
In preparation for performing the selective deposition of the first operation, the conformable portion of the CC mask is placed in registration with and pressed against a selected portion of the substrate (or onto a previously formed layer or onto a previously deposited portion of a layer) on which deposition is to occur. The pressing together of the CC mask and substrate occur in such a way that all openings, in the conformable portions of the CC mask contain plating solution. The conformable material of the CC mask that contacts the substrate acts as a barrier to electrodeposition while the openings in the CC mask that are filled with electroplating solution act as pathways for transferring material from an anode (e.g. the CC mask support) to the non-contacted portions of the substrate (which act as a cathode during the plating operation) when an appropriate potential and/or current are supplied.
An example of a CC mask and CC mask plating are shown in
Another example of a CC mask and CC mask plating is shown in
Unlike through-mask plating, CC mask plating allows CC masks to be formed completely separate from the fabrication of the substrate on which plating is to occur (e.g. separate from a three-dimensional (3D) structure that is being formed). CC masks may be formed in a variety of ways, for example, a photolithographic process may be used. All masks can be generated simultaneously, prior to structure fabrication rather than during it. This separation makes possible a simple, low-cost, automated, self-contained, and internally-clean “desktop factory” that can be installed almost anywhere to fabricate 3D structures, leaving any required clean room processes, such as photolithography to be performed by service bureaus or the like.
An example of the electrochemical fabrication process discussed above is illustrated in
Various components of an exemplary manual electrochemical fabrication system 32 are shown in
The CC mask subsystem 36 shown in the lower portion of
The blanket deposition subsystem 38 is shown in the lower portion of
The planarization subsystem 40 is shown in the lower portion of
Another method for forming microstructures from electroplated metals (i.e. using electrochemical fabrication techniques) is taught in U.S. Pat. No. 5,190,637 to Henry Guckel, entitled “Formation of Microstructures by Multiple Level Deep X-ray Lithography with Sacrificial Metal layers”. This patent teaches the formation of metal structure utilizing mask exposures. A first layer of a primary metal is electroplated onto an exposed plating base to fill a void in a photoresist, the photoresist is then removed and a secondary metal is electroplated over the first layer and over the plating base. The exposed surface of the secondary metal is then machined down to a height which exposes the first metal to produce a flat uniform surface extending across the both the primary and secondary metals. Formation of a second layer may then begin by applying a photoresist layer over the first layer and then repeating the process used to produce the first layer. The process is then repeated until the entire structure is formed and the secondary metal is removed by etching. The photoresist is formed over the plating base or previous layer by casting and the voids in the photoresist are formed by exposure of the photoresist through a patterned mask via X-rays or UV radiation.
Even though electrochemical fabrication as taught and practiced to date, has greatly enhanced the capabilities of microfabrication, and in particular added greatly to the number of metal layers that can be incorporated into a structure and to the speed and simplicity in which such structures can be made, room for enhancing the state of electrochemical fabrication exists. For example, formation of individual masks for each layer can be expensive and time consuming. Such individualized masks must also be recreated for even minor design changes. A need exists in the field for a simplified manner and less restrictive manner for obtaining selective deposition of material in an electrochemical fabrication process.
SUMMARY OF THE INVENTIONIt is an object of various aspects of the present invention to provide a less restrictive technique for obtaining selective deposition of material.
It is an object of various aspects of the present invention to provide a simplified electrochemical fabrication process.
Other objects and advantages of various aspects of the invention will be apparent to those of skill in the art upon review of the teachings herein. The various aspects of the invention, set forth explicitly herein or otherwise ascertained from the teaching herein, may address any one of the above objects alone or in combination, or alternatively may address some other object of the invention ascertained from the teachings herein. It is not intended that all of, or necessarily any of, the above objects be addressed by any single aspect of the invention even though that may be the case with regard to some aspects.
In a first aspect of the invention a process for forming a multilayer three-dimensional structure includes (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate and for forming process pockets when such proximate or contact positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) selectively etching material from the substrate or previously deposited material to form at least one void, including applying a desired electrical activation to at least one selected cell electrode and to the substrate; and (5) depositing a selected material into at least a portion of the at least one void.
In a second aspect of the invention a process for forming a multilayer three-dimensional structure includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate for forming electrochemical process pockets when such proximate or contact positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) modifying the substrate or previously deposited material at selected locations, including applying desired electrical activation to at least one selected cell electrode and to the substrate; and wherein a plurality of the cells of the multi-cell mask include a passage in proximity to the cell electrode for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between one or more electrodes located outside the process pockets and a portion of the substrate forming part of at least one pocket.
In a third aspect of the invention a process for forming a multilayer three-dimensional structure includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of cells of the mask include a control means for selectively activating or inhibiting activation of the cell during an electrochemical process, and wherein a pattern of dielectric material extends beyond the control means for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is made; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; and (4) selectively depositing a desired material onto the substrate or previously deposited material or selectively forming voids in the substrate or previously deposited material, including applying a desired activation to at least one control element that is used to control the activity of a selected cell, and applying a desired electrical activation to the substrate, and to one or more additional electrodes that may be located within individual cells or located external to the multi-cell mask.
In a fourth aspect of the invention a process for forming a multilayer three-dimensional structure includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate positioning relative to the substrate and for forming electrochemical process pockets when such proximate positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning without achieving complete contact sealing between all of the extended dielectric material and the substrate such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; and (4) selectively depositing a desired material onto the substrate or previously deposited material, including applying a desired electrical activation to at least one desired cell electrode and to the substrate.
In a fifth aspect of the invention a process for forming a multilayer three-dimensional structure includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is achieved; (3) selectively depositing a desired material onto the substrate or previously deposited material, including applying a desired electrical activation to at least one desired cell electrode and to the substrate, wherein the process additionally includes one or more of: (c) at least one multi-cell mask controlled etching operation to remove or reduce thin depositions of material from regions where no deposition was intended where the etching operation may be, for example, a chemical etching operation or an electrochemical etching operation; (d) at least one blanket etching operation to remove or reduce thin depositions of material from regions where no deposition was intended and where the etching operation may be, for example, a chemical etching operation or an electrochemical etching operation; (e) adjusting the size of the selective deposition region to at least partially accommodate for any dimensional changes associated with an etching operation; (f) providing variable deposition heights associated with different cells by using different deposition control parameters; (g) turning off deposition for a cell when a short is detected, and if the deposition time is less than that anticipated to yield a desired overall deposition depth, separating the mask and the substrate, reseating the mask and substrate, etching the substrate to reduce excess height, and then continuing with deposition; (h) orbiting the mask during deposition to cause deposition over a larger region than that defined by the cell alone; (i) after selective deposition with a first multi-cell mask is completed for a given layer, performing an etching operation with at least a second multi-cell mask where the cells of the second multi-cell mask have a configuration more closely matching the size and shape of any regions of excess deposition that resulted from overlapping depositions from use of the first multi-cell mask; (j) wherein some operations use at least one mask with a first sized opening while other operations use at least one mask with a second sized opening where the first and second sized openings are different; (k) wherein some operations use at least one mask having a first opening orientation and at least one mask having a second orientation wherein the first and second orientations are different; and/or (l) wherein the multi-cell mask and the substrate are brought into proximate or contact positioning such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions on a previous layer, wherein the desired registration results in the location of at least some depositions being offset from nearest corresponding deposition locations used for a previous deposition made in association with the formation of a previous layer and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets.
In a sixth aspect of the invention a process for forming a multilayer three-dimensional structure includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements they may be used in at least one of activating or deactivating the cells; (3) bringing the multi-cell mask and the substrate into proximate positioning without achieving contact sealing between cells of the mask and the substrate and providing a desired electrolyte solution such that the solution is provided between the mask and the substrate; and (4) selectively depositing a desired material onto the substrate or previously deposited material or selectively etching a material from the substrate or previously deposited material, including applying a desired electrical activation to at least one desired cell electrode and to the substrate.
In a seventh aspect of the invention a process for modifying a substrate, including: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials wherein the forming of at least one layer includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate and for forming process pockets when such proximate or contact positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) selectively etching material from the substrate or previously deposited material to form at least one void, including applying a desired electrical activation to at least one selected cell electrode and to the substrate; and (5) depositing a selected material into at least a portion of the at least one void.
In an eighth aspect of the invention a process for modifying a substrate includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials, wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred and will occur; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate for forming electrochemical process pockets when such proximate or contact positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) modifying the substrate or previously deposited material at selected locations, including applying desired electrical activation to at least one selected cell electrode and to the substrate; and wherein a plurality of the cells of the multi-cell mask include a passage in proximity to the cell electrode for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between one or more electrodes located outside the process pockets and a portion of the substrate forming part of at least one pocket.
In a ninth aspect of the invention a process for modifying a substrate includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials, wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred and will occur; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of cells of the mask include a control means for selectively activating or inhibiting activation of the cell during an electrochemical process, and wherein a pattern of dielectric material extends beyond the control means for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is made; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; and (4) selectively depositing a desired material onto the substrate or previously deposited material or selectively forming voids in the substrate or previously deposited material, including applying a desired activation to at least one control means that is used to control the activity of a selected cell, and applying a desired electrical activation to the substrate, and to one or more additional electrodes that may be located within individual cells or located external to the multi-cell mask.
In a tenth aspect of the invention a process for modifying a substrate includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials, wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is achieved; (3) selectively depositing a desired material onto the substrate or previously deposited material, including applying a desired electrical activation to at least one desired cell electrode and to the substrate, wherein the process additionally includes one or more of: (c) at least one multi-cell mask controlled etching operation to remove or reduce thin depositions of material from regions where no deposition was intended where the etching operation may be, for example, a chemical etching operation or an electrochemical etching operation; (d) at least one blanket etching operation to remove or reduce thin depositions of material from regions where no deposition was intended and where the etching operation may be, for example, a chemical etching operation or an electrochemical etching operation; (e) adjusting the size of the selective deposition region to at least partially accommodate for any dimensional changes associated with an etching operation; (f) providing variable deposition heights associated with different cells by using different deposition control parameters; (g) turning off deposition for a cell when a short is detected, and if the deposition time is less than that anticipated to yield a desired overall deposition depth, separating the mask and the substrate, reseating the mask and substrate, etching the substrate to reduce excess height, and then continuing with deposition; (h) orbiting the mask during deposition to cause deposition over a larger region than that defined by the cell alone, and/or (i) after selective deposition with a first multi-cell mask is completed for a given layer, performing an etching operation with at least a second multi-cell mask where the cells of the second multi-cell mask have a configuration more closely matching the size and shape of any regions of excess deposition that resulted from overlapping depositions from use of the first multi-cell mask (j) wherein some operations use at least one mask with a first sized opening while other operations use at least one mask with a second sized opening where the first and second sized openings are different; (k) wherein some operations use at least one mask having a first opening orientation and at least one mask having a second orientation wherein the first and second orientations are different; and/or (l) wherein the multi-cell mask and the substrate are brought into proximate or contact positioning such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions on a previous layer, wherein the desired registration results in the location of at least some depositions being offset from nearest corresponding deposition locations used for a previous deposition made in association with the formation of a previous layer and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets.
In an eleventh aspect of the invention a process for forming a multilayer three-dimensional structure includes: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials, wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements they may be used in at least one of activating or deactivating the cells; (3) bringing the multi-cell mask and the substrate into proximate positioning without achieving contact sealing between cells of the mask and the substrate and providing a desired electrolyte solution such that the solution is provided between the mask and the substrate; and (4) selectively depositing a desired material onto the substrate or previously deposited material or selectively etching a material from the substrate or previously deposited material, including applying a desired electrical activation to at least one desired cell electrode and to the substrate.
In a twelfth aspect of the invention a multi-cell mask includes: a plurality of independently controllable cells, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for contact or proximate positioning relative to a substrate and for forming substantially independent electrochemical process pockets when such contact is made or proximite positioning is obtained and wherein a passage extends through the cells thereby providing a passage from the process pockets to a region outside the process pockets.
In a thirteenth aspect of the invention a multi-cell mask includes: a plurality of independently controllable cells, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements, and wherein the mask is capable of proximate positioning relative to a substrate and for forming electrochemical process pockets associated with each cell.
In a fourteenth aspect of the invention an apparatus for forming a multilayer three-dimensional structure includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a mask having multiple cells, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for contacting the substrate and for forming process pockets when such contact is made; (c) at least one stage for bringing the multi-cell mask and the substrate into contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; (d) at least one power supply for selectively etching material from the substrate or previously deposited material to form at least one void, including means for applying desired electrical power to the substrate and to selected cell electrodes; (e) means for depositing a selected material into at least a portion of the voids; (e) at least one computer programmed for repeatedly controlling the stage, selected cell electrodes, the supply of power from the power supply to cause selective etching of the substrate, and the deposition means to deposit the selected material into at least the portion of the voids to form depositions of material on previously formed layers when forming a desired structure from a plurality of layers.
In a fifteenth aspect of the invention an apparatus for forming a multilayer three-dimensional structure includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a mask having multiple cells, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements, and wherein a pattern of dielectric material extends beyond the cell control elements for contacting the substrate and for forming substantially independent electrochemical process pockets when such contact is made; (c) at least one stage for bringing the multi-cell mask and the substrate into contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; (d) at least one power supply for modifying the substrate or previously deposited material at selected locations, including applying desired electrical activation to at least one selected cell electrode and to the substrate; and; (e) at least one computer programmed for repeatedly controlling the stage, selected cell control elements, the supply of power from the power supply; wherein a plurality of the cells of the multi-cell mask include a passage in proximity to the control elements for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between one or more electrodes located outside the process pockets and a portion of the substrate forming part of at least one pocket.
In a sixteenth aspect of the invention an apparatus for forming a multilayer three-dimensional structure includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of cells of the mask include a control means for selectively activating or inhibiting activation of the cell during an electrochemical process, and wherein a pattern of dielectric material extends beyond the control means for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is made; (c) at least one stage for bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; and (d) at least one power supply for applying a desired activation to at least one control elements that are used to control the activity of selected cells, and selectively depositing a desired material onto the substrate or previously deposited material or selectively forming voids in the substrate or previously deposited material, including means for applying a desired electrical activation to the substrate, and to one or more additional electrodes that may be located within individual cells or located external to the multi-cell mask, and; (e) at least one computer programmed for repeatedly controlling the stage, selected cell control elements, the supply of power from the at least one power supply.
In a seventeenth aspect of the invention an apparatus for forming a multilayer three-dimensional structure includes: (a) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements they may be used in at least one of activating or deactivating the cells; (c) a stage for bringing the multi-cell mask and the substrate into proximate positioning without achieving contact sealing between cells of the mask and the substrate and providing a desired electrolyte solution such that the solution is provided between the mask and the substrate; and (d) a power supply for selectively depositing a desired material onto the substrate or previously deposited material or selectively etching a material from the substrate or previously deposited material, including applying a desired electrical activation to at least one desired cell electrode and to the substrate; and (e) at least one computer programmed for repeatedly controlling the stage, selected cell control elements, the supply of power from the at least one power supply.
In an eighteenth aspect of the invention an apparatus for modifying a substrate includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a mask having multiple cells, wherein each cell is separated from other cells by a material, wherein the cells of the mask include independently controllable electrodes, and wherein a pattern of dielectric material extends beyond the cell electrodes for contacting the substrate and for forming process pockets when such contact is made; (c) at least one stage for bringing the multi-cell mask and the substrate into contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; (d) at least one power supply for selectively etching material from the substrate or previously deposited material to form at least one void, including applying desired electrical power to the substrate; and (e) means for depositing a selected material into at least a portion of the at least one void.
In a nineteenth aspect of the invention an apparatus for modifying a substrate includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a mask having multiple cells, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements, and wherein a pattern of dielectric material extends beyond the cell control elements for contacting the substrate and for forming substantially independent electrochemical process pockets when such contact is made; (c) at least one stage for bringing the multi-cell mask and the substrate into contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; (d) at least one power supply for modifying the substrate or previously deposited material at selected locations, including applying desired electrical activation to at least one selected cell electrode and to the substrate; and wherein a plurality of the cells of the multi-cell mask include a passage in proximity to the control elements for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between one or more electrodes located outside the process pockets and a portion of the substrate forming part of at least one pocket.
In a twentieth aspect of the invention an apparatus for modifying a substrate includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of cells of the mask include a control means for selectively activating or inhibiting activation of the cell during an electrochemical process, and wherein a pattern of dielectric material extends beyond the control means for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is made; (c) at least one stage for bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; and (d) at least one power supply for selectively depositing a desired material onto the substrate or previously deposited material or selectively forming voids in the substrate or previously deposited material including applying a desired activation to at least one control elements that are used to control the activity of selected cells, and applying a desired electrical activation to the substrate, and to one or more additional electrodes that may be located within individual cells or located external to the multi-cell mask, such that a desired material is selectively deposited onto the substrate or such that one or more voids are formed in the substrate.
In a twenty-first aspect of the invention an apparatus for modifying a substrate includes: (a) a substrate on which one or more successive depositions of one or more materials may have occurred; (b) a multi-cell mask, wherein each cell is separated from other cells by a material, wherein the cells of the mask include control elements they may be used in at least one of activating or deactivating the cells; (c) a stage for bringing the multi-cell mask and the substrate into proximate positioning without achieving contact sealing between cells of the mask and the substrate and providing a desired electrolyte solution such that the solution is provided between the mask and the substrate; and (4) a power supply for selectively depositing a desired material onto the substrate or previously deposited material or selectively etching a material from the substrate or previously deposited material including applying a desired electrical activation to at least one desired cell electrode and to the substrate.
In a twenty-second aspect of the invention a process for forming a multilayer three-dimensional structure, including: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, including: (i) a reusable portion including a material separating individual cell regions and at least one independently controllable electrode associated with each cell to control activation of each respective cell; and (ii) a separate portion that is positioned on the substrate or previous formed layer with a desired alignment and position and where the separate portion provides a dielectric barrier in a boundary region between each cell of the reusable portion; (3) bringing the reusable portion of the multi-cell mask into proximate positioning or contact with the separate portion such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) selectively depositing material to the substrate or previously deposited material or etching material from the substrate or previously deposited material to form at least one void, including applying a desired electrical activation to at least one selected cell electrode and to the substrate.
In a twenty-third aspect of the invention a process for forming a multilayer three-dimensional structure, including: (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials; (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers; wherein the forming of at least one layer, includes: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a mask having at least one cell that is smaller than or equal to the desired resolution that will be used in modifying the substrate, wherein the at least one cell includes at least one independently controllable cell electrode, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate for forming a process pocket when such proximate or contact positioning is achieved; (3) bringing the mask into proximate positioning or contact with the substrate or previously deposited material such that an electrochemical process pocket is formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pocket; (4) selectively depositing material to the substrate or previously deposited material or etching material from the substrate or previously deposited material to form at least one void, including applying a desired electrical activation to at least one cell electrode and to the substrate; (5) moving the mask to a plurality of new locations and repeating operation (4) a plurality of times.
Further aspects of the invention will be understood by those of skill in the art upon review of the teachings herein. Other aspects of the invention may involve combinations of the above noted aspects of the invention. Other aspects of the invention may involve apparatus that can be used in implementing one or more of the above method aspects of the invention. Still other aspects may involve use of the multi-cell masks set forth herein for forming single layers. Still other aspects of the invention may provide multi-cell masks configured according to the various embodiments set forth herein or generalizations thereof. These other aspects of the invention may provide various combinations of the aspects presented above as well as provide other configurations, structures, functional relationships, and processes that have not been specifically set forth above.
The various embodiments, alternatives, and techniques disclosed herein may be used in combination with electrochemical fabrication techniques that use different types of patterning masks and masking techniques or even techniques that perform direct selective depositions without the need for masking. For example, conformable contact masks and masking operations may be used, proximity masks and masking operations (i.e. operations that use masks that at least partially selectively shield a substrate by their proximity to the substrate even if contact is not made) may be used, non-conformable masks and masking operations (i.e. masks and operations based on masks whose contact surfaces are not significantly conformable) may be used, and adhered masks and masking operations (masks and operations that use masks that are adhered to a substrate onto which selective deposition or etching is to occur as opposed to only being contacted to it) may be used.
A simple example of a controllable multi-cell mask and a sample deposition created therefrom is illustrated in
In some embodiments the array of subanodes is covered with a patterned elastomeric material that extends beyond the plane of the electrodes such that a pocket is formed around each anode having a width that establishes the effective size of the anode and a depth (e.g. as small as 10 microns, or less, to as large as one to several hundred microns, or even larger) appropriate for holding an electrolyte and allowing a desired electrochemical reaction to occur. The regions defined by the anode, the dielectric may be considered the cells of the mask, in this embodiment, and regions additionally defined by a substrate to which the mask is positioned in proximity to or brought into contact with, may be considered as process pockets associated with the cells of the mask Each anode may be formed of the desired material to be deposited (e.g. copper) or it may be formed of a non-erodable conductor (e.g. platinum or highly doped silicon) on which a quantity of deposition material is placed. A pattern of elastomeric material 114 is illustrated in
In other embodiments, the elastomeric material may be replaced by a conformable material that is non-elastomeric or by even a material that is relatively rigid without significant conformability. In embodiments where a rigid contact material is used there may be an increased likelihood of flash which may be removed or reduced by application of a selective etching operation or by a relatively short or gentle bulk etching operation of the electrochemical or chemical type. In embodiments where a relatively rigid contact material is used, flexibility across the width of the mask may be obtained by a support structure, that connects some or all of the anodes together, having some flexibility or by a more conformable material being located between the anodes and the contact material. Such alternatives for providing overall flexibility to a mask that uses a relatively rigid contact material are further described in U.S. Provisional Application No. 60/429,484 filed Nov. 26, 2003 by Cohen et al, and entitled “Non-Conformable Masks and Methods and Apparatus for Forming Three-Dimensional Structures”. This application is incorporated herein by reference.
In some embodiments, the mask may include a dielectric material that is disassociated from the rest of the mask (e.g. electrodes and separating dielectric). In these alternative embodiments the disassociated dielectric may be patterned onto a substrate or previously deposited material. It may be planed (if necessary, e.g. by machining or lapping) and patterned in a desired manner. The patterning of the disassociated dielectric material may define cells of similar resolution to that defined by the separate portion of the mask. Such embodiments may benefit from accurate placement of the disassociated masks but may not require as accurate a placement of the portion of the mask that contains the electrodes as slight misplacements of the two may have little negative impact on the deposited or etched material. Examples of materials that may be used to form such disassociated masks include liquid photoresists (of the negative or positive type), dry film photoresists (of the negative or positive type), and photopolymers. Patterning of such materials may occur via normal exposure through photomasks followed by development, direct scanned UV laser exposure followed by development, or even direct laser ablation. An advantage to such an approach is that a single photomask or a small set of photomasks may be used to produce a wide range of structures.
As noted above each anode of the smart mask is independently controlled. This may be achieved, for example, through its formation on an integrated circuit that offers control capability or through conductive paths that lead from the back side of the mask, or through the dielectric material located between the subanodes, to appropriate control circuitry. In still further alternatives, control may be provided via a reduced set of control lines via multiplexed configuration of control lines and circuitry. The multiplexer may power individual cells directly or it may supply power to storage capacitors, or the like, associated with each cell which in turn supplies a steadier level of current and/or potential to selected subanodes.
When the mask is pressed against a substrate and the subanodes are turned on in a specific pattern, a selective deposit of that pattern occurs.
In other embodiments, the offsetting and deposition patterns could have been performed using more than four sets of operations (e.g. positioning, seating, and deposition operations) and/or different deposition patterns could have been used after each positioning operation. If the required final deposition pattern allowed it, fewer than four sets of operations could have been performed. Deposits such as that in
In alternative embodiments, the subanode dimensions, the subanode spacing, and the positioning accuracy associated with the offsets may be selected such that little or no overlap occurs between successive depositions, i.e. between pattern filling depositions, associated with forming a given layer. In still further alternative embodiments, different smart masks having different deposition patterns or sizes may be used for successive (i.e. shifted) depositions such that overlap is minimized while still ensuring lateral contact between deposits.
Subanodes may be periodically “redressed” so that the mask can be used multiple times. In the case of a multi-cell mask that is used for deposition, redressing may occur by plating deposition material onto the subanodes. Prior to beginning a redressing operation, if the subanodes are formed of a non-erodable material (e.g. platinum or silicon), any remaining deposition material on the subanodes to be redressed can be removed and then redressing can begin with a known starting point. In some embodiments, the extended dielectric material is preferably not mounted to the erodable material but in other embodiments it may be. In some embodiments, the extended dielectric material is mounted to a second dielectric that separates the electrodes from another or alternatively is mounted to a combination of a second dielectric and a non-erodable conductive material where the depositable material is plated onto the non-erodable material within the cells defined by the extended dielectric material.
It can be determined which subanodes should be redressed, and potentially by how much, by simply tracking their deposit history individually. Alternatively, the subanodes may be tested periodically to ensure that they are working properly. For example, a test may be performed before a deposition onto a substrate and after a deposition onto the substrate. If the prior test showed that each subanode was working correctly, the subanode is used for the deposition onto the substrate. If after deposition, the subanodes are retested, and it is found that one or more of the anodes failed the test then selected depositions on the substrate can be examined for their appropriateness and/or the deposition on the substrate can be removed and the selectively deposition operation repeated with a different mask, with the same mask but after redressing, or deposition to only selected portions of the substrate can be repeated but this time using different cells of the mask.
Cells that remain defective, even after attempts to redress them, may be flagged and their use avoided during successive plating operations or otherwise compensated for by performing additional plating operations with offsets to position working cells to positions previously occupied by the faulty cells.
While the use of N exposures (e.g. 4 exposures) will result in an N-fold (e.g. fourfold), or more, increase in deposition time compared with EFAB using structure specific masks, overall process time may not increase by such a large factor as the process typically includes other operations as well. If the EFAB process is similar to that set forth in the background (i.e. with one blanket deposition operation and one planarization operation per layer), the overall process time, for example if four exposures are used will probably not double.
In preferred embodiments, the elastomer is thick and/or compliant enough that it can accommodate for the thickness of a deposit generated during a previous exposure (i.e. previous deposition) and still provide good masking with minimal and preferably no flash as the mask attempts to mate over any discontinuity between the deposit and the substrate below. To minimize the effects of large discontinuities, planarization operations can occur more frequently than once per layer.
In alternative embodiments, discontinuities may be minimized by only making partial layer thickness depositions per pass and then repeating the four or more steps a plurality of times (this may be termed “cycling”). It may be beneficial to implement cycling when layer thickness is above 1–2 microns such that the thickness added by any single deposition remains under about 1 micron.
In other alternative embodiments, instead of using the multi-cell mask to perform deposition operations, the multi-cell mask may be used to perform etching operations. In these alternatives, much of the above discussion still applies but the cells of the mask no-longer contains subanodes but instead may be considered to contain subcathodes. Such masks may be considered to be of the Mask-on-Cathode (MOC) type.
Differential in deposition height or etching depth from an active cell may occur due to differential amounts of time that different portions of the region are exposed to deposition or etching conditions. As a cell is shifted through its four or more deposition positions, if there is some overlap between the positions (e.g. near the center of the region) the overlapped regions will receive a different amount of deposition or etching than the non-overlapped regions. Differential in deposition may not matter in a build process that will include a planarization operation on each layer.
However, when planarization is not to occur on each layer, it may be desirable to even out the deposition thickness. This evening out may occur in a multi-cell selective deposition embodiment by etching with one or more additional multi-cell masks (e.g. a second mask and possibly a third mask or even a fourth multi-cell mask) where the cell patterns and positions of these patterns are set to correspond to the regions of overlap (e.g. quadruple overlap, double overlap, and the like). In embodiments where the resolution is considered to correspond to the approximate area that is to be covered by each cell (i.e. a given cell is either off or on for all exposures of a deposition and offsetting pattern), as the overlap positions associated with cells are dictated by the cell shape and the offsetting technique used, these overlap patterns will have fixed shapes that can be accommodated by only one or a few additional masks. For example if it is desired to bring the net deposition height down to approximately the deposition thickness associated with the non-overlapped region, then the quadruple overlap mask may be used to etch the quadruple exposed region down to the level of a double exposure, while the double overlap mask may include the quadruple overlap region and it may be used to reduce the thickness down to the non-overlap thickness.
Differentials in etching depth within a given cell's etching region may also be problematic and may require intervention using multi-cells masks having cell configurations that correspond to different etching overlap levels (quadruple overlap, double overlap, and like). These additional masks may be used to plate material into the over etched regions to bring the approximate level of the entire regions to the non-overlapped etching depth in a manner analogous to the way it was done for evening out deposition differentials.
Of course in alternative approaches, masks with patterns corresponding regions where non-maximal etching occurred or non-maximal deposition occurred (e.g. double deposition or etching as opposed to quadruple deposition or etching, and single deposition or etching as opposed to quadruple deposition or etching could be used to cause additional deposition or etching such that the amount deposited throughout the region would be equal to the maximum amount deposited or etched. This approach may not provide a saving in time but it may provide a savings in material consumption.
In still other embodiments, the width of the cells could be made to match the width of the regions separating the cells such that upon offsetting no overlap would occur. In still other embodiments it may be possible to use masks having effective deposition or etching widths that are slightly smaller than the offset used between depositions (e.g. the effective deposition width of a cell of the mask may be slightly less than one-half the width of the region to be deposited to by the cell) where it is anticipated that any gaps between the offset deposition regions will be filled in by as a result of the conformable contact material's inability to enter narrow deposition gaps such that material becomes deposited in to the gaps
In still other embodiments MOA type masks and MOC type masks may be replaced with anodeless and cathodeless masks in that the anode and cathode (at least as far as plating or etching operations is concerned) is not located on or within each cell of the mask but instead is separate from them. Each cell will include a passage that will, under appropriate conditions, allow ion flow between the substrate and an anode or cathode that is remotely positioned (typically within a volume of electrolyte that is larger than the volume of electrolytes within the process pockets). Each cell will include at least one control electrode or other control element that can be effectively used to allow or inhibit passage of ions to or from the substrate and thus can be used to selectively control which cells allow deposition or etching and which cells do not.
In the some embodiments of the present invention it is important to understand that it may not be necessary to completely eliminate deposition or etching in regions protected by inactive cells (i.e. cells that are not supposed to allow deposition or etching) but instead it may only be necessary to create a sufficient deposition or etching differential (e.g. greater then 5 to 1, more preferably greater than 10 to 1 and most preferably greater than 20 to 1). If necessary, small amounts of deposition within inactive cell regions may be removed by performing a short or gentle etching operation either in a selective manner (e.g. material selectively or region selective, or both) or in a bulk manner. Etching may occur via either electrochemical etching or chemical etching.
If necessary, small amounts of etching from inactive regions may be neutralized via a planarization operation that removes material such that voids created by undesired etching are removed and thereafter additional deposition or etch steps can be continued. The planarization operation may be followed by a cleaning operation that ensures planarization debris is removed from the intended etching voids. As an alternative to planarization or as a complement thereto, a selective deposition operation can be performed using the multi-cell mask where a slight amount of deposition is made to occur within those inactive cells where the material that may have been inadvertently etched into is the same as the material that is being deposited.
In still further alternatives, if control of active and inactive cells is difficult, multi-cell masks that contain through passages and non-erodable electrodes may be used in a multi-operation process to perform selective deposition and/or etching. To perform a deposition operation from a remote source to the substrate, the following two operations may be performed:
1. Treating the remote source as an anode and the active cell electrodes as cathodes and proceeding with depositing material from the remote source on to the active cell electrodes. During this part of the operation the substrate would be left at a floating potential. The inactive cells may also be at a floating potential or at a potential equal to or greater than that of the remote source. During this process, it is preferred that the cell electrode within the inactive cell remain free of any deposition material.
2. Removing the potential from the remote source and letting it float or alternatively removing the remote source from the electrolyte. Treating the active cell electrodes as anodes and treating the substrate as a cathode. Allowing deposition to occur. During this operation the potential on the electrodes in the inactive cells is preferably the same as or greater than the potential on the active cells. Depending on the flow restrictions it may be possible for the potential on the inactive cells to remain floating. A flow restriction that would allow such a floating potential to be used may involve a second non-erodable electrode in each cell positioned to be further away from the substrate than the electrode that is actively involved in the operations. The potential on this second electrode would be higher than that on the other cell electrode such that it provides a barrier to positive ions leaving the cell. In a further alternative, the second electrode may be coated with a thin dielectric such that it cannot not participate in charge transfer while still allowing it to participate in forming an electrostatic barrier. As necessary, the mask may be shifted to ensure deposition to all appropriate locations.
To perform an etching operation from the substrate to a remote material depository, two operations analogous to those set forth above may be used. For example, two such operations might include:
1. Treating the substrate as an anode and the active cell electrodes as cathodes and proceed with etching material from the substrate and depositing it on to the active cell electrodes. During this part of the operation the remote depository is left at a floating potential or even removed from the bath of electrolyte. The inactive cells are held at the substrate potential or somewhat higher and they are preferably free of any erodable material. In an alternative embodiment the cell electrodes in the inactive cells are allowed to float but a second set of possibly insulated electrodes in the inactive cells may be set at a potential equal to or greater than that of the substrate. As necessary the mask may be shifted relative to the substrate to ensure etching of all appropriate locations.
2. Removing the potential from the substrate and letting it float. Treating the active cell electrodes as anodes and treating the remote depository as a cathode. Allowing deposition from the active cell electrodes to the depository to occur. The inactive cell electrodes may be left floating or may be powered at the same potential as the active cell electrodes.
When used herein, located “in proximity to” or being “proximate to” when referring to relative locations of a mask and a substrate shall be construed to mean close enough spaced such that deposition or etching from one cell has minimal, or certainly no more than an acceptable amount of deposition to or etching from the regions associated with neighboring cells. If etching operations, or planarization operations are used to minimize the effects of undesired deposits or voids created by etching of undesired regions, the extent of what is considered to be acceptable amounts of peripheral deposition or etching may be increased.
In alternative embodiments a rigid dielectric material may be used to support the cell electrodes while more conformable or even an elastomeric dielectric may be used for contacting the substrate. In further alternative embodiments the cells may include more than one electrode wherein one or more of the electrodes are insulated by a dielectric material (e.g. a thin coating of dielectric). In still further alternative embodiments, the cell electrodes can have appendages and or crisscross grids of elements that extend into or even completely across the passages 224. The appendages or electrode grids may be exposed to electrolyte and thus be able to directly receive and or give up material or they may be coated with dielectrics. In still further alternative embodiments some or all of the cell electrodes may take the form of porous conductive structures 212′(1,2)-212′(4,2) as shown in
References V1–V6 indicate that each cell electrode may take an independent potentials or at least potentials that are selected between two or more values. The potential selected for each cell electrode determines whether the cell is active (allows deposition or etching) or is inactive (inhibits deposition or etching). EA and Vi may be looked at in different ways: (1) fixed voltages or voltage differentials or (2) simply as potentials that give current flow a particular direction and whose magnitude is only relevant relative to other elements in the electric path.
For deposition (e.g. electroplating) to occur onto the substrate for selected cells, the ion source will function as an anode (+ potential) and the substrate will act as a cathode (− potential). Active cells (i.e. the cells that allow deposition) may be allowed to have floating potential (i.e. no potential that is fixedly maintained) though in some embodiments they may be given a potential somewhere in between that of the anode and that of the cathode. The inactive cells (i.e. the cells which will inhibit plating) preferably have a potential at least as large as that of the ion source and maybe even somewhat higher. Since the cell electrode for the inactive cells presents a higher potential than the ion source, ions will be inhibited from entering the cells. Thus significant plating on the portion of the substrate bounded by the cell is inhibited. Preferably the cell electrodes are of a non-erodable material such as platinum or silicon but an erodable material may be acceptable if the potential differences are such that significant erosion doesn't occur or current densities are such that significant plating onto the substrate doesn't occur. In some alternative embodiments where the cell electrodes are used solely for creating appropriate electrical potentials (as in the present embodiment) and do not participate in current carrying functions of the system, the cell electrodes may be isolated from the electrolyte (e.g. plating solution) by a dielectric material.
For electrochemical etching, element 318, the depository, functions as a cathode (− potential) while the substrate functions as an anode (+ potential). The active cell electrodes preferably have floating potentials though in some embodiments it may be possible to set their potentials at something intermediate to the cathode and anode potentials. Inactive cell electrodes preferably have a potential as great as that of the substrate or more preferably somewhat greater.
In plating embodiments, the space within the cells is filled an electrolyte 322 that extends from the cathode (i.e. substrate) to the anode (i.e. the ion source). In etching embodiments, the cells are filled with an electrolyte that may also function as a plating solution. In some embodiments the same mask and plating solution may be used for both plating and etching operations by reversing the polarities of the various electrodes.
The system of
As plating with the masks discussed above may result in some deposition into the inactive cells it is probable that after selective deposition an electrochemical bulk or selective etch (e.g. via the same multi-cell mask) could be performed for a limited time to remove any unwanted deposits while not significantly damaging the original depositions. A bulk or selective chemical etch could also be performed.
In the case of bulk etching for cleaning up of unwanted depositions, the original selective deposition data could be modified to accommodate for any XY shrinkage of the selectively deposited material.
In other words, if the X and Y half widths are equal, then the offsets between depositions are +/−2*HW (i.e. or plus or minus the width of the dielectric between cell openings, W=Wx=Wy) along one or both of the axes. To achieve the same deposition pattern these offsets may be taken any order and even combined. Besides changing the order of depositions and thus changing the offsetting pattern, other offset patterns may be used. For example, similar deposition patterns may be obtained by using different cells to deposit to the different parts of a given region. Such a mixed cell deposition pattern may be obtained by shifting cells along one or both axes by one or more region widths (2*HWx+EDWx in X or 2*HWy+EDWy in Y) and adding or subtracting the dielectric width (2*HWx in X or 0.2*HWy). In other words, the offsets may be
N*(2*HWx+EDWx)+/−2*HWx in X
and/or
N*(2*HWy+EDWy)+/−2*HWy in Y.
In other embodiments, other offsets may be used while still achieving both intra-cell and inter-cell overlap. For example, individual cells may be used in depositing material to other cell regions by adding to or subtracting from the increments set forth above by an integral number of widths of the entire region (i.e. “EDWx+2*HWx” along the X axis or “EDWy+2*Hwy” along the Y axis).
In practice, this type of non-overlapping deposition pattern may be used where the resolution is defined as being related to the region size or to the EDW for each cell. If the resolution is to be related to the region size, then during deposition individual cells may receive an active or inactive command that would apply to each deposition in the pattern, whereas if the EDW is to dictate the resolution the active or inactive status of each cell would need to be updated for each deposition operation depending on whether the next deposition location is receive a deposit or not.
Other non-overlapping deposition embodiments are possible where the nominal region width (NRW) is an integral multiple of the EDW. These other embodiments may use more than two depositions locations for each cell along the X and/or the Y axes such that the number of depositions to complete a layer increases beyond 4 (e.g. 6 for a 3×2 region, or 9 for a 3×3 region).
Still other non-overlapping deposition embodiments may use an NRW that is somewhat larger than an integral multiple of the EDW. Embodiments of this type might be more preferable in some circumstances as they may be able to avoid unintended overlaps in deposits that might result from tolerances in EDW or NRW sizing or tolerances in positioning resolution. If the widths of the openings in the mask are just slightly smaller than the width of the dielectric material that separates the openings, it is believed imperfect conformability of the dielectric will inhibit the dielectric from completely closing the small gap between a region to be deposited. This inability to completely close the gap will result in the previous and current depositions contacting one another. This is illustrated in
As noted elsewhere herein, in other embodiments, the shape of the cells may take other forms and/or the pattern of the cells may take other forms. Examples of such shapes and patterns are illustrated in
Another example of a two step embodiment is illustrated with the aid of
In alternative embodiments to those illustrated in
As discussed herein above, in some embodiments due to the presence of overlapped depositions, non-uniformity of deposition height may be problematic. In some embodiments, this problem may be addressed by use of planarization operations to smooth the deposits. In other embodiments, selective etching may be used to enhance the uniformity of the deposition. An example of this type of technique is illustrated with the aid of the deposition pattern of
After the first deposition, as shown in
Ignoring possible flash related depositions that might occur as a result of imperfect mating between the mask and the substrate (especially in those regions that transition from one deposition height to another) and assuming that all four depositions that are within the region are used to deposit material, the four step pattern doesn't yield a uniform deposition depth but instead some portions of the region receive a single unit of deposition height, some receive two units of deposition height, and some receive four units of deposition height. A unit of deposition may be any height which is assumed to be the same for each deposition operation in this example but need not be in other embodiments. If the entire layer thickness is to be achieved by these four depositions, the height of deposit may be equal to that of the layer thickness or may be somewhat larger. If instead, multiple repetitions of this four step process are to occur, then the height of one unit may be a fraction of the layer thickness.
A potential problem with the resulting deposition pattern is that it doesn't have anything approaching a uniform deposition depth. In this example, the height of the deposition will vary by a factor of four. This may be non-problematic in some circumstances (e.g. when planarization will be used to bring the height of deposition down to a desired level, such as to the one unit height assuming the cost of deposition material, deposition time, planarization time, and the like are not too high).
As discussed above, an implementation of a deposition height or etching depth differential reduction technique may involve performing the reverse of a portion of the deposition or etching using specially shaped cells in a multi cell instant mask. As also discussed above, other alternatives may add to the results of a deposition or etching by additional deposition or etching using specially shaped cells.
One additional mask and etching operation may be used to bring the deposit differential down from 4:1 to 2:1. This extra mask could be used in a single etching operation to reduce all of the “4” unit depositions down to a lower level (e.g. a two unit level or even a one unit level).
If it were desired to bring the net deposition differential down even further, a desired mask pattern could be used to etch the portions of the deposit that are thicker down to match the height of the thinner deposit (e.g. etch the two unit height down to a height of about one unit). Alternatively, additional material may be deposited (e.g. using a mask having cells with an appropriate pattern) to the thinner portion of the deposition to bring it closer to the height of the thicker portion of the deposit (e.g. to bring the height of the one unit thick portion to about the height of the two unit portion). The additional etching operations may involve 2 or more offsets with specially configured cells.
For example the mask of
Though the above approach of depositing extra material and then selectively etching away the excess material achieves the desired result, it may not be as time efficient as an approach that deposits material so that the overlapped portions (e.g. the portions that receive multiple deposits) reach the desired height while the non-overlapped portions are subsequently filled in using one or more masks of desired configuration.
As discussed elsewhere herein, some embodiments may use bubble formation to control the activity of individual cells of a multi-cell mask. In an embodiment that doesn't contact the masks against the substrate during deposition, it is possible that multi-step plating will not be necessary. In other words, a single position of the cells may be able to plate all appropriate portions of the substrate. If the bubbles seal the cells and possibly partially locate themselves under the cell dielectric boundaries, three unique situations can occur at cell boundary lines: (1) Off-cell meets off-cell—no depositions within cells and no depositions under cell dividers; (2) Off-cell meets on-cell—deposition in on-cell—no deposition in off-cell—extent of deposition under cell dividers depends on the extent the bubbles are located under the dividers; and (3) On-cell meets on-cell—depositions in the cells—deposition under the dividers (height of deposition is limited to that of the spacing between the dividers and the substrate).
Variations of these three situations can occur. In particular the final deposition position and boundary shape in situation (2) can impact the accuracy of the final structure and the surface finish of a series of stacked layers. In situation (3) if the divider is too close to the substrate the entire region under the divider may not fill in prior to the deposit on each side sealing against the divider.
It is believed that in some embodiments it may be possible to perform the mask and substrate set up, cell activation (and/or deactivation), and the deposition operations such that entire layers may be formed using single depositions. It is also believed that the process may be performed such that the position of boundary lines between deposition and non-deposition zones may be sufficiently predictable that the original structure/object/device data may be modified to enhance the accuracy of the final produced structure. It may also be possible to tailor the process, mask cell divider shape, etc. so that boundary shape is also optimized.
An example of a mask and two sample depositions are shown in
From
In alternative embodiments many features of the embodiment of
In still further alternatives, the bottom surface of the dielectric dividers may contain bubble producers and such masks bubble producers may allow use of masks where the physical dielectric doesn't extend below the cell electrodes and maybe even where the dielectric doesn't completely extend to the bottom of the cell electrodes. This is illustrated in
In still other alternatives, the orientation of the mask and substrate of
In still further embodiments, the bubble's may not need to contact the substrate. In these alternatives, the sealing between the mask and the substrate may be caused by contact between the cell dividers and the substrate where the bubbles are simply used as cell inactivators/controllers.
In still other alternative embodiments, the spacing between the substrate and the mask and the divider width may be sufficient to limit depositions to individual cell regions with or without formation of bubbles that bridge the space between the mask and the substrate. An example of this is illustrated in
In alternatives embodiments,
In still further alternatives, the masks containing anodes may be replaced by anodeless-type masks. For bubble forming embodiments this alternative is particularly enabled by the substrate being on top so that bubbles don't escape from the cells. This alternative may work in the mask-on-top approach if the passages are bridged by a porous structure that inhibits the passage of bubbles or where surface tension effects reliably hold the bubbles in place.
Other multi-cell programmable mask embodiments may involve varying the cell divider height. The divider height could be made high where transitions from active cell regions to inactive cell regions occur such that those dividers could seal the mask to the substrate. Dividers separating active cells from one another or inactive cells from one another could be set low so they would not contact the substrate. In these embodiments it may be preferable to have the dividers along each wall of each cell to be capable of independent movement. The divider height sets, seals, and separates the active and inactive regions from each other as well as allows flow between all connected cells of a single type. Each cell is still preferably independently controlled for deposition or no deposition.
The heights of the dividers may be set in various ways. For example, in some embodiments, the height of the dielectric may be set by pushing it against an appropriate pattern (e.g. a programmable solenoid or electrostatically controlled bed of rods) that can set the dielectric to a high or low state. The dielectric may, for example be heated when it is pressed against the bed to place it in a modifiable state so that its shape may be adjusted. It may be cooled prior to removing it from the bed to lock it into position before removing it from the contouring pattern. This method of setting divider height is illustrated in
In some alternative embodiments, if the mating properties (e.g. deformability or elasticity) of the selected shape memory material are inappropriate to obtain the desired conformity for sealing the mask and the substrate, the shape memory material may have a region of conformable material applied to its surface (e.g. PDMS).
A second embodiment may achieve differential height of the dielectric divider material by contacting the dividers to a material that will temporally adhere to them. This material may be selectively applied to the transitional boundaries to increase their height. After mating and deposition the temporary material may be removed and a new pattern of extender material may be applied to the multi-cell mask's transitional dividers. The extender material may be a material deposited directly onto the divider or may be a material that is first patterned onto a different surface and then transferred to the dividers; The material may, for example, be applied by ink (such as a wax-like material). It may be a toner that is deposited electrostatically.
An example of a transfer approach is shown in
Another example of a transfer approach is shown in
In the above differential height embodiments, the created masks are used to contact the substrate such that the entire region can be patterned by a deposition in a single process; however in other embodiments proximity positioning of the mask relative to the substrate might allow adequate separation of the deposition and the non-deposition regions.
In some embodiments cell position may be aligned from layer-to-layer while in other embodiments cell positioning may be shifted between consecutive or periodic layers. In still other embodiments, cell size may be varied on different layers or even varied within a layer. Embodiments that vary cell alignment positioning or cell sizing may yield structures with different mechanical properties than similarly configured structures that are produced when cell alignment is maintained fixed from layer-to-layer. Such formation techniques are contrasted in
In further embodiments different cell size relationships may be used and different offsetting or shifting parameters may be used. Deposition may not concern itself with maintaining layer size or feature position with regard to an original design concept but instead may base layer size and/or feature position on the desired cell alignment positions and quantization thus associated with each layer. The quantization may determine whether or not any given cell position is a deposition position or not based on some predefined criteria. Examples of such criteria include: (1) formation of over-sized structures in that any data calling for material presence within a given deposition position may dictate that the deposition is to occur, (2) formation of undersized structures in that for a determination of a deposition position to receive deposition the entire position must possess data that indicates that material is to be present, (3) an averaged sized approach in that determination of deposition may be based on the percentage of a given deposition position for which the data indicates material is to exist.
In alternative embodiments the cell electrodes can take on different forms ranging from porous structures to peripheral rings. For example, a cross of conductive material may extend to the center of a cell or a line of conductive material may be suspended in the center of a cell. In still other alternatives the cell electrodes may be segmented and multiple feeds used to apply a variety of potentials to a single cell. In some embodiments, the conductive material of the electrodes may be exposed to the electrolyte while in other embodiments they may be isolated from the electrolyte.
In still further embodiments, the cell electrodes may be provided with a sufficient potential difference relative to the other electrodes that a significant amount of gas may be produced (e.g. via hydrolysis or vaporization) that could help limit etching from the inactive cells. If bubble generation is found to be unproductive or otherwise bothersome, agitation or electrolyte flow may be used to sweep bubbles away such that problems with etching from active cells are minimized.
In various alternative embodiments, layer build up may occur from a combination of selective depositions of one or more materials from a multi-cell programmable mask. Other alternatives could use a combination of selective depositions from a multi-cell programmable mask and from one or more structure or device specific masks. In other embodiments, selective deposition from multi-cell programmable masks may be combined with blanket depositions. In still other embodiments, planarization operations may be used after deposition of all material for a given layer and/or intermediate to the deposition of all material for a given layer.
In various other alternatives, selective etching may be performed in combination with selective depositions and/or blanket depositions. Various electrochemical fabrication techniques that use etching are described in the previously referenced U.S. Pat. No. 6,027,630 and in U.S. patent application Ser. No. 10/434,519, filed May 7, 2003 by Smalley, and entitled “Methods of and Apparatus for Electrochemically fabricating Structure Via Interlaced Layer of Via Selective Etching and Filling of Voids”. This patent application is incorporated herein by reference as if set forth in full. Selective etching In still other alternatives, holes of varying depth or deposits of varying thickness may be generated by varying the pattern of active cells. The changing of patterns may occur in the middle of a deposition. The changing of patterns may occur during a shifting of the deposition pattern from one location to another. In other embodiments, the mask may be separated from the substrate in the middle of a deposition to allow the electrolyte to be refreshed.
In various other embodiments, specific cells can be turned on or off independent of the switching on and off of other cells. In this regard certain locations can undergo longer or shorter depositions as desired. For example, if an electrical short is detected, the shorted cell can be turned off. The shorted cell can undergo a reversal in polarity in an attempt to eliminate the nodule or other feature that caused the short. If necessary, the mask may be lifted away from the substrate to break contact with the nodule, be reseated, and then a reversal in polarity implemented in an attempt to eliminate or reduce the nodule prior to attempting to complete the deposition
In various other embodiments, the cell control electrode may be replaced or supplemented by other control elements. Multiple cell electrodes may be located in each cell. Some cell electrodes may be insulated by a dielectric. The control elements can take various forms with the intent that they allow cells to toggle between active and inactive states. For example, heating elements may be included in the cells to form gas bubbles that can block or significantly limit the ability of ions to be conducted to or from the substrate thereby causing formation of an inactive cell. The cell can be made active again in various ways. For example, the cell may be reactivated by separating the mask and the substrate and introducing a vibration, agitation, or flow of electrolyte in the region of the cell to dislodge or otherwise remove or eliminate the bubble. Bubble formation may be made to occur in a variety of ways. For example, bubble formation may occur by creating sufficient resistive heat or radiative heat to vaporize a small quantity of liquid in the electrolyte or by passing an electrical current through the electrolyte within the cell so a portion of the liquid undergoes hydrolysis (i.e. from 2H2O to 2H2 and 2O2). Other control elements may be used to cause the movement of mechanical element from an open position (active) to a closed position (inactive) via an electrostatic or magnetic force. Still other control elements may use cooling to freeze or otherwise lower the mobility of ion transfer through an inactive cell.
In some embodiments a surface of the dielectric forming the grid of cells will contact the substrate to form a seal around each cell while in other embodiments the dielectric forming the grid of cells will not contact the substrate but will be located close enough to it (in proximity to it) to cause a reasonable amount of isolation between deposition and/or etching operations in adjacent cells (for example to yield an effective ratio of deposition height or etching depth in active cells to that in inactive cells of 5 or greater or even 10 or greater). In embodiments that use a bubble formation to create inactive cells, bubbles formed against the substrate may aid in forming a seal between the inactive cell and any active adjacent cells. In still other embodiments, the dielectric forming the grid of cells may have indentations or ridges on its contact surface to inhibit complete sealing between the mask and the substrate. This incomplete sealing may be useful when bubble formation is used to inactivate cells as it may leave small flow paths for displaced liquid to escape. In other embodiments, cell energization (i.e. transition to and from active and inactive states) may occur in a predefined order. The predefined ordered may be selected, for example, to minimize the risk of trapping excess electrolyte (e.g. via bubble formation) within a portion of the mask.
In embodiments where, proximate positioning is used between a mask and the substrate, instead of holding a given deposition/etching position for a time, then stopping deposition/etching, making a transition to a new position, and then restarting deposition/etching, it may be possible to simply perform a continuous orbit within a desired deposition/etching region for a desired period of time. The orbiting pattern may be selected to give a desired pattern of differential deposition/etching. If the width of deposition/etching region is at least twice the width of a cell it may be possible to achieve uniform deposition or etching if an appropriate orbiting pattern is selected.
While the disclosure herein has focused primarily on the use of multi-cell masks for deposition purposes, other embodiments may also be used to selectively etch material in a manner largely analogous to the techniques used for depositing material with the distinction that in partially overlapped etching operations corners of etched material may be removed more quickly than planar regions and thus sharp cornered regions may become rounded. This is illustrated in
In some embodiments where the cells of the mask will be used for etching, it may be preferable to set the region width to somewhat larger than an integral number of cell widths such that tolerances in size and positioning ensure that overlapping etching regions do not initially occur but such that small regions of separation will be readily removed by the etching operations and that any overlapping etching is minimized.
Multi-cell masks may be fabricated in a variety of ways including the use of electrochemical fabrication on integrated circuits that act as substrates, molding operations, or ablation operations (e.g. to shape dielectric materials), use of electrochemical fabrication (e.g. via deposition specific masks) to form electrodes and conductive paths, and etching operations may be used to make passages, and the like. In some embodiments photoresist processing techniques may be used to form patterned masks.
In some embodiments of the present invention a means for depositing material may be used. This means may provide a selective deposition or a blanket deposition. This means may include a multi-cell mask or other mask if the deposition is to be selective. The means may include various components that are useful for applying a material to the substrate in a variety of ways, such as for example: (1) electroplating, (2) electrophoretic deposition, (3) electrostatic deposition (4) chemical vapor deposition, (5) physical vapor deposition, (5) spraying such as thermal spray metal deposition, (6) flinging of a liquefied material or a material in a binder or other carrier, (7) spreading such as by brush, doctor blade, or roller, (8) ink jet deposition, (9) contacting, spinning, and drying or otherwise curing. Techniques for forming three-dimensional structure using thermal spray metal deposition processes are described in U.S. Provisional Patent Application No. 60/422,008, filed on Oct. 29, 2003 by Lockard, entitled “EFAB methods and apparatus including spray Metal Coating Processes”. This application is incorporated herein by reference as if set forth in full. The means may take on various other forms or may be a combination of apparatus implementing the above processes. The specific elements that may be used with the above noted processes, and variations thereof are well understood. Other deposition means will be apparent to those of skill in the art upon review of the teachings herein. Some alternative means may be described in the various publications and patents incorporated herein by reference.
In some embodiments of the present invention it may be possible to separate the multi-cell masks into two or more pieces. For example, the portion of the mask that contacts the substrate may be formed on the substrate while the portion of the mask that contains the electrodes, and the like, may be contacted against an already adhered grid pattern of dielectric material. The gird pattern of dielectric material that is adhered to the substrate may be formed from patterned photoresist, photopolymer or the like. Embodiments with such split multi-cell masks may have the advantage of requiring less precise positioning of the active part of the mask so long as the adhered portion is placed with adequate precision.
In some embodiments the controllable masks may be reduced to a single cell that can be used to draw out a desired deposition much like a pen is used to draw patterns one dot or line at a time. In still other alternative embodiments, the single cell may be used to cause selective etching of various portions of a substrate or portions of a partially formed layer. In still further embodiments the grid of multi-cell masks may be configured in a linear array much like some ink jet print heads are arrayed.
Various other embodiments of the present invention exist. Some of these embodiments may be based on a combination of the teachings herein with various teachings incorporated herein by reference. Some embodiments may not use any blanket deposition process and/or they may not use a planarization process. Some embodiments may involve the selective deposition of a plurality of different materials on a single layer or on different layers. Some embodiments may use blanket depositions processes that are not electrodeposition processes. Some embodiments may use selective deposition processes on some layers that are not electrodeposition processes. Some embodiments may use nickel as a structural material while other embodiments may use different materials such as gold, silver, or any other electrodepositable materials that can be separated from the copper and/or some other sacrificial material. Some embodiments may use copper as the structural material with or without a sacrificial material. Some embodiments may remove a sacrificial material while other embodiments may not. In some embodiments, the depth of deposition will be enhanced by pulling the conformable contact mask away from the substrate as deposition is occurring in a manner that allows the seal between the conformable portion of the CC mask and the substrate to shift from the face of the conformal material to the inside edges of the conformable material.
In view of the teachings herein, many further embodiments, alternatives in design and uses of the instant invention will be apparent to those of skill in the art. As such, it is not intended that the invention be limited to the particular illustrative embodiments, alternatives, and uses described above but instead that it be solely limited by the claims presented hereafter.
Claims
1. A process for forming a multilayer three-dimensional structure, comprising:
- (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials;
- (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers;
- wherein the forming of at least one layer, comprises: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of the cells of the mask each comprise an independently controllable electrode, and wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate and for forming process pockets when such proximate or contact positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) selectively etching material from the substrate or previously deposited material to form at least one void, comprising applying a desired electrical activation to at least one selected cell electrode and to the substrate; and (5) depositing a selected material into at least a portion of the at least one void,
- wherein a plurality of the cells of the multi-cell mask comprise a passage in proximity to the cell electrode for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between the substrate and one or more electrodes located outside the process pockets.
2. The process of claim 1 wherein selected cells are activated in a manner to allow selective deposition on to the substrate to occur such that any inadvertent etching of material from those cells is at least partially compensated for.
3. The process of claim 1 wherein the formation of the one or more voids on a given layer comprises a plurality of selective etching operations using a multi-cell mask wherein at least a portion of the etching operations have positions that are offset from previous etching positions.
4. The process of claim 1 wherein, the operation of at least a portion of the cells of the multi-cell mask is tested by etching material using the mask and examining the resulting depositions.
5. The process of claim 4 wherein an algorithm is used to avoid reliance on etching from any cells found to be faulty, wherein the algorithm comprises one or more of:
- a. avoidance of etching using a faulty cell by positioning the faulty cell in a location not requiring etching,
- b. performing an extra etching operation by positioning a non-faulty cell at a required position if a faulty cell was at that position during a previous etching operation or is anticipated to be at that position during a subsequent etching operation,
- c. selecting a multi-cell-mask from a plurality of multi-cell masks where the selection is made such that no faulty cells exist on the selected multi-cell mask in regions that will be used for etching, or
- d. attempting to redress any faulty cells by removing any material that may be inhibiting successful operation of the cell, retesting at least the faulty cells of the mask, and proceeding with use of the mask if the fault has been eliminated.
6. The process of claim 1 wherein a multi-cell mask is used to perform depositions on a plurality of layers of the three-dimensional structure.
7. The process of claim 1 wherein at least one material deposited on a plurality of layers comprises a sacrificial material and wherein the sacrificial material is removed to expose a desired three-dimensional structure.
8. The process of claim 1 wherein during formation of at least one layer a multi-cell mask is used for both etching and depositing material.
9. The process of claim 1 additionally comprising orbiting the mask during etching to cause etching by an individual cell to cover a larger region than that defined by dimensions of the cell.
10. A process for forming a multilayer three-dimensional structure, comprising:
- (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials;
- (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers;
- wherein the forming of at least one layer, comprises: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of the cells of the mask each comprise an independently controllable electrode, wherein a pattern of dielectric material extends beyond the cell electrodes for proximate or contact positioning relative to the substrate for forming electrochemical process pockets when such proximate or contact positioning is achieved; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is located within the electrochemical process pockets; (4) modifying the substrate or previously deposited material at selected locations, comprising applying desired electrical activation to at least one selected cell electrode and to the substrate; and
- wherein a plurality of the cells of the multi-cell mask comprise a passage in proximity to the cell electrode for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between one or more electrodes located outside the process pockets and a portion of the substrate forming part of at least one pocket,
- wherein the modifying of the substrate or previously deposited material further comprises activating at least one electrode outside the process pockets,
- wherein during deposition onto the substrate, inactive cells have their cell electrodes set at a potential equal to or greater than that of an anode.
11. The process of claim 10 wherein the modification to the substrate includes a deposition of material.
12. The process of claim 10 wherein each process pocket operates substantially independently from other process pockets in its ability to modify the substrate or previously deposited material.
13. The process of claim 10 wherein the modifying of the substrate or previously deposited material results in a modification of the substrate or previously deposited material in active pockets being at least five times greater than modification of the substrate or previously deposited material in inactive pockets.
14. The process of claim 10 wherein the modifying of the substrate or previously deposited material results in a modification of the substrate or previously deposited material in active pockets being at least ten times greater than modification of the substrate or previously deposited material in inactive pockets.
15. The process of claim 10 wherein the modification to the substrate includes an etching of material to form one or more voids, and wherein the process additionally comprises depositing a selected material into at least a portion of the voids.
16. The process of claim 10 wherein a multiple step modification process is used wherein material is transferred to the cell electrode from either the substrate or from an electrode outside the process pockets and at least a portion of the material on the cell electrode is transferred to the other of the electrode outside the process pockets or the substrate, respectively.
17. The process of any of claim 15 wherein the formation of a given layer begins with an initial deposition of a material and then proceeds to using a multi-cell mask to etch voids into the deposited material.
18. The process of claim 17 wherein between the initial deposition and the etching operation, a planarization operation occurs.
19. The process of claim 15 wherein a blanket deposition operation deposits material into the voids after etching.
20. The process of claim 10 wherein at least one material deposited on a plurality of layers comprises a sacrificial material and wherein the sacrificial material is removed to expose a desired three-dimensional structure.
21. The process of claim 15 wherein the deposition of material comprising an electroplating of material on to the substrate.
22. The process of claim 10 wherein at least a portion of the cells comprise multiple independently controllable electrodes.
23. The process of claim 15, wherein during selective etching from the substrate, active cells have their cell electrodes set at a floating potential.
24. The process of claim 15, wherein during selective etching from the substrate, inactive cells have their cell electrodes set at a potential equal to or greater than that of the substrate.
25. The process of claim 10 wherein during deposition onto the substrate, active cells have their cell electrodes set at a floating potential.
26. The process of claim 10, wherein a selective or bulk etching operation is used to remove or at least reduce any thin depositions that occur in inappropriate locations.
27. The process of claim 10 wherein the deposition regions are modified to at least partially account for any distortion that may result from any etching operations.
28. A process for forming a multilayer three-dimensional structure, comprising:
- (a) forming a layer of at least one material on a substrate that may include one or more previously deposited layers of one or more materials;
- (b) repeating the forming operation of “(a)” one or more times to form at least one subsequent layer on at least one previously formed layer to build up a three-dimensional structure from a plurality layers;
- wherein the forming of at least one layer, comprises: (1) supplying a substrate on which one or more successive depositions of one or more materials may have occurred; (2) supplying a multi-cell mask, wherein each cell is separated from other cells by a material, wherein each of a plurality of the cells of the mask comprise a control means for selectively activating or inhibiting activation of the cell during an electrochemical process; and wherein a pattern of dielectric material extends beyond the control means for proximate or contact positioning relative to the substrate and for forming electrochemical process pockets when such proximate or contact positioning is made; (3) bringing the multi-cell mask and the substrate into proximate positioning or contact such that electrochemical process pockets are formed having a desired registration with respect to any previous depositions and providing a desired electrolyte solution such that the solution is provided within the electrochemical process pockets; and (4) selectively depositing a desired material onto the substrate or previously deposited material or selectively forming voids in the substrate or previously deposited material, comprising applying a desired activation to at least one control element that is used to control the activity of a selected cell, and applying a desired electrical activation to the substrate, and to one or more additional electrodes that may be located within individual cells or located external to the multi-cell mask,
- wherein a plurality of the cells of the multi-cell mask comprise a passage in proximity to the cell electrode for allowing ion exchange between the electrolyte in the process pockets and a larger volume of electrolyte located outside the process pockets such that ions may be transferred between the substrate and one or more electrodes located outside the process pockets.
29. The process of claim 28 wherein at least a plurality of control elements each comprise at least two electrodes to which a desired electrical activation can be applied such that a current is conducted through a cell to cause formation of at least one gas bubble that inhibits the ability of that cell to contribute to deposition on or etching from an associated portion of the substrate.
30. The process of claim 28 wherein at least a plurality of control elements each comprise a heating element that locally elevates the temperature of the electrolyte within a cell sufficiently to cause formation of at least one gas bubble that inhibits the ability of that cell to contribute to deposition on or etching from an associated portion of the substrate.
31. The process of claim 28 wherein at least a plurality of control elements each comprise a mechanical element that can be shifted by heating or electrostatic action between an active position and an inactive position.
32. The process of claim 28 wherein at least a plurality of control elements each comprise a temperature changing component that can contribute to causing either one or both of increasing or lowering the mobility of ion transportation within a cell relative to other cells such that a sufficient differential in deposition or etching between cells occurs such that a desired selectivity is obtained.
33. The process of claim 28 wherein at least a plurality of control elements are used to control a plurality of cells, with each control means comprising at least one electrode to which a desired electrical activation can be applied such that current flow from a region outside the pockets to a region inside the pockets is allowed or inhibited.
34. The process of claim 28 wherein at least a plurality of control elements each comprise a radiation source that can cause formation of at least one gas bubble that inhibits the ability of that cell to contribute to deposition on or etching from an associated portion of the substrate.
35. The process of claim 28 wherein at least a portion of the dielectric material that extends beyond the cell electrodes comprises a conformable material.
36. The process of claim 28 wherein an end of the conformable material includes ridges or depressions that inhibit complete sealing between the conformable material and the substrate such that electrolyte can migrate between cells if the control means creates excess pressure on the liquid within a cell.
37. The process of claim 28 where activation of the control means originates from deeper interior regions within the multi-cell mask and works outward toward peripheral regions of the mask.
38. The process of claim 28 wherein a plurality of the cells of the multi-cell mask comprise a source of deposition material or an electrode for receiving etched material from the substrate.
39. The process of claim 28 wherein a desired material is selectively deposited onto the substrate via the multi-cell mask.
40. The process of claim 28 wherein material is selectively etched from the substrate via the multi-cell mask.
41. The process of claim 28 wherein a single multi-cell mask is used for both selectively etching and for selectively depositing material.
42. The process of claim 28 wherein the mask and substrate are not brought into intimate contact but are positioned in close enough proximity to one another to allow selective deposition or etching to occur such that a ratio in deposition height or etching depth between active cells and inactive cells is at least a factor of five.
43. The process of claim 42 wherein the factor is at least ten.
Type: Grant
Filed: Oct 1, 2003
Date of Patent: Jun 26, 2007
Patent Publication Number: 20040134788
Assignee: Microfabrica Inc. (Van Nuys, CA)
Inventors: Adam L. Cohen (Los Angeles, CA), Dennis R. Smalley (Newhall, CA), Gang Zhang (Monterey Park, CA)
Primary Examiner: Nam Nguyen
Assistant Examiner: Luan V. Van
Attorney: Dennis R. Smalley
Application Number: 10/677,498
International Classification: C25D 5/02 (20060101);